3d printable hard ferrous metallic alloys for powder bed fusion

ABSTRACT

Alloy compositions for 3D metal printing procedures which provide metallic parts with high hardness, tensile strengths, yield strengths, and elongation. The alloys include Fe, Cr and Mo and at least three or more elements selected from C, Ni, Cu, Nb, Si and N. As built parts indicate a tensile strength of at least 1000 MPa, yield strength of at least 640 MPa, elongation of at least 3.0% and hardness (HV) of at least 375.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No. 17/248,953 filed Feb. 15, 2021, which is a continuation of U.S. application Ser. No. 16/393,194 filed Apr. 24, 2019 that issued as U.S. Pat. No. 10,953,465 on Mar. 23, 2021, which is a continuation-in-part of U.S. application Ser. No. 15/800,210 filed Nov. 1, 2017 that issued as U.S. Pat. No. 10,920,295 on Feb. 16, 2021, and claims the benefit of U.S. Provisional Application Ser. No. 62/415,667 filed Nov. 1, 2016, the disclosures of which are hereby incorporated by reference herein.

FIELD

The present disclosure relates to alloy compositions and 3D printing procedures to provide for the formation of metallic parts with relatively high hardness, tensile strengths, yield strengths, and elongation. The alloys also indicate the ability to form desirable phases, such as metal carbide and/or metal carbonitride phases, that contribute to such mechanical property characteristics.

BACKGROUND

Metal 3D printing processes provide a multitude of exceptional benefits such as the ability to produce highly complex parts with largely reduced part production time. For these reasons 3D printing is of high value to many industries. While many 3D printing processes for building metal parts exist, the most widely adopted processes are those that utilize solid-liquid-solid phase transformations to build parts. These processes are commonly referred to as powder bed fusion (PBF), selective laser melting (SLM), and electron beam melting (EBM), hereinafter these processes are referred to as PBF.

While PBF is exceptionally versatile in its ability to produce complex parts from specific metal alloys, the process has been limited to being able to produce parts from relatively few alloy steels such as 316L, 17-4PH and maraging steel M300. Among these alloys, only M300 has a hardness that is considered sufficient to classify the alloy as a hard alloy (HV>370).

Expanding the material breadth of hard PBF steel alloys has met a variety of issues foremost among which is the occurrence of crack formation upon or after the printing process. Cracking of parts can be caused by a number of factors such as thermal stresses, hot cracking, and liquation cracking, and generally the potential for cracking increases as the hardness of the built parts increases and the toughness decreases.

Numerous industries have a great deal of interest in utilizing PBF with higher hardness materials (HV>370) for applications such as tooling, dies, molds, cutting tools, gears, filters, and bearings. In addition to high hardness these applications typically also require high strength, toughness, and corrosion resistance, low environmental health, low safety and stewardship risk, and low cost.

SUMMARY

A method of layer-by-layer construction of a metallic part comprising supplying an iron-based alloy in particle form including the elements Cr and Mo wherein Cr is present at 10.0 wt. % to 19.0 wt. %, Mo is present at 0.5 wt. % to 3.0 wt. % and at least three elements from C, Ni, Cu, Nb, Si and N, wherein C is present at 0 to 0.35 wt. %, Ni is present at 0 to 4.0 wt. %, Cu is present at 0 to 5.0 wt. %, Nb is present at 0 to 1.0 wt. %, Si is present at 0 to 1.0 wt. % and N is present at 0 to 0.25 wt. %; the balance of said alloy composition containing Fe; and forming one or more layers of the alloy by melting the alloy into a molten state and cooling and forming a solidified layer of the elements wherein each of the solid layers has a thickness as formed of 2.0 microns to 200.0 microns. The metallic part comprising one or more layers has the following properties: tensile strength of at least 1000 MPa, yield strength of at least 640 MPa, elongation of at least 3.0%, hardness (HV) of at least 375. In the above composition, Mn may replace Ni.

The present invention also relates to a 3D printed metallic part comprising one or more iron based metallic alloy layers including the elements Cr and Mo wherein Cr is present at 10.0 wt. % to 19.0 wt. %, Mo is present at 0.5 wt. % to 3.0 wt. % and at least three elements from C, Ni, Cu, Nb, Si and N, wherein C is present at 0 to 0.35 wt. %, Ni is present at 0 to 5.0 wt. %, Cu is present at 0 to 5.0 wt. %, Nb is present at 0 to 1.0 wt. %, Si is present at 0 to 1.0 wt. % and N is present at 0 to 0.25 wt. % and the balance of said alloy composition contains Fe; said layers having thickness in the range of 2.0 microns to 200.0 microns; and said printed metallic part indicates a tensile strength of at least 1000 MPa, yield strength of at least 640 MPa, elongation of at least 3.0%, and hardness (HV) of at least 375.

In the above composition, Mn may replace Ni.

The present invention also relates to a method of layer-by-layer construction of a metallic part comprising: supplying an iron-based alloy in particle form comprising Fe at 82.0 wt. % to 86.0 wt. %; Cr at 10.5 to 12.0 wt. %; Ni at 1.5 to 2.5 wt. %; Mo at 0.8 wt. %. to 1.1 wt. %, C at 0.14 to 0.19 wt. %, Nb at 0.02 to 0.06 wt. %, N at 0.04 to 0.09 wt. % and Si at 0.25 wt. % to 0.75 wt. %; and forming one or more layers of the alloy by melting the alloy into a molten state and cooling and forming a solidified layer of the elements wherein each of the solid layers has a thickness as formed of 2.0 microns to 200.0 microns; said metallic part having the following properties: tensile strength of at least 1000 MPa, yield strength of at least 640 MPa, elongation of at least 3.0%, hardness (HV) of at least 375.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 is an optical image of alloy 1 (A10) built on a SLM 280 HL machine.

FIG. 2 is an optical image of alloy 1 (A10) built on a Trumpf TRUMAFORM LF 250 PBF machine.

FIG. 3 is an optical image of alloy 1 (A10) built on an EOS machine with a density >99.5%.

FIG. 4 shows a 10,000×SEM micrograph of as-built alloy 1 (A10).

FIG. 5 shows the alloy 1 equilibrium phase diagram produced with Thermo-Calc.

FIG. 6 shows microstructures at the surface of a part made of alloy 5 (Table 1) at two different magnifications after carburization.

FIG. 7 shows hardness as a function of depth in a carburized case hardened alloy 5 and alloy 8 (Table 1).

FIG. 8 shows microstructures at the surface of a part of alloy 9 (Table 1) at two different magnifications after nitriding.

FIG. 9 shows hardness as a function of depth in a nitrided case hardened alloy 8 and 9 (Table 1).

DETAILED DESCRIPTION

A new class of steel alloys have been developed that combine excellent printability with, in both the “as built” and in the “heat treated” state, high hardness (>375 HV), high yield and tensile strength, and high elongation as well as low safety (EH&S) and stewardship risk and relatively low cost.

Printability of an alloy is defined as the ease of printing a metal alloy on a variety of commercial PBF machines without cracking or excessive porosity in the built parts. The as-built condition is understood herein as the condition of the PBF built parts upon removal from the PBF machine, i.e. without any post-build heat treatment. The heat treated condition is understood herein as the condition of the PBF built parts that have been subjected to a post-build heat treatment. The alloys herein are capable of 3D printing which refers to a process to create a three-dimensional object.

Table 1 below sets out the alloy chemistries that are preferably employed herein, which includes alloy 1 (A10) and then 11 additional alloys for a total of 12 alloys:

TABLE 1 Alloy Chemistries (Wt. %) Alloy Fe C Cr Ni Cu Nb Mo Si N Mn 1 (A10) 84.93 0.16 10.64 1.96 0.54 0.03 1.48 0.19 0.07 0 2 84.92 0.25 11.5 1 0.5 0.03 1.5 0.25 0.05 0 3 84.97 0.2 11.5 1 0.5 0.03 1.5 0.25 0.05 0 4 84.96 0.16 11.5 1.05 0.59 0.04 1.51 0.18 0 0 5 84.57 0.21 11.21 1.93 0.12 0.03 1.7 0.19 0.04 0 6 81.66 0.21 15.55 0.88 0.55 0.03 0.89 0.16 0.07 0 7 82.82 0.21 11.69 0.94 2.56 0.06 1.47 0.17 0.08 0 8 86.85 0.1 10.56 0 0.56 0.04 1.61 0.14 0.14 0 9 85.37 0.17 11.01 1.85 0 0.04 0.95 0.53 0.074 0 10 86.64 0.12 10.55 0 0.55 0.08 1.52 0.39 0.14 0 11 87.03 0.11 11.03 0 0 0.08 1.38 0.2 0.16 0 12 84.19 0.23 10.6 0 0.69 0.04 1.99 0.39 0.133 1.74

Accordingly, it can be appreciated from the above that one supplies a metal alloy in particle form comprising, consisting essentially of, or consisting of Fe, Cr and Mo, wherein Cr is present at 10.0 wt. % to 19.0 wt. %, Mo is present at 0.5 wt. % to 3.0 wt. % and at least three or more elements from C, Ni, Cu, Nb, Si and N, wherein C is present at 0 to 0.35 wt. %, Ni is present at 0 to 5.0 wt. %, Cu is present at 0 to 5.0 wt. %, Nb is present at 0 to 1.0 wt. %, Si is present at 0 to 1.0 wt. % and N is present at 0 to 0.25 wt. %. The balance of said alloy composition contains Fe. Accordingly, one may select four elements, five elements or all six elements from C, Ni, Cu, Nb, Si and N for a given alloy formulation.

In a preferred embodiment, one again supplies a metal alloy in particle form comprising, consisting essentially of, or consisting of Fe, Cr and Mo, wherein Cr is present at 10.0 wt. % to 18.3 wt. %, Mo is present at 0.5 wt. % to 2.5 wt. % and at least three or more elements from C, Ni, Cu, Nb, Si and N, wherein C is present at 0 to 0.30 wt. %, Ni is present at 0 to 4.0 wt. %, Cu is present at 0 to 4.0 wt. %, Nb is present at 0 to 0.7 wt. %, Si is present at 0 to 0.7 wt. % and N is present at 0 to 0.25 wt. %. The balance of said alloy composition contains Fe.

Furthermore, the alloy may include some amount of inevitable impurities wherein the level of such impurities may be up to 1.0 wt. %, For example, an element not listed above may also be present at a level of up to 1.0 wt. %, where the corresponding level of Fe can then be reduced 1.0 wt. %. With regards to impurities, it is noted that such is contemplated to include elements such as sulfur, phosphorous and oxygen.

Alloy 1, which was previously designated as alloy A10, may itself have the following preferred composition: Fe at 82.0 to 86.0 wt. %; Cr at 10.5 to 12.0 wt. %; Ni at 1.5 to 2.5 wt. %; Cu at 0.4 to 0.7 wt. %; Mo at 1.2 to 1.8 wt. %, C at 0.14 to 0.18 wt. %, Nb at 0.02 to 0.05 wt. %, N at 0.04 to 0.07 wt. % and Si at 0-1.0 wt. %.

In addition to the above, it has also been found that with respect to the use of any Ni in the aforementioned alloys, which as noted may be present at a level of 0 to 5.0 wt. %, one may replace the presence of any such Ni with Mn at 0 to 5.0 wt. %. Accordingly, the metal alloy herein in particle form may also comprise, consist essentially of, or consist of Fe, Cr. Mo, wherein Cr is present at 10.0 wt. % to 19.0 wt. %, Mo is present at 0.5 wt. % to 3.0 wt. %, and at least three or more elements from C, Mn, Cu, Nb, Si and N, where C is present at 0 to 5.0 wt. %, Mn is present at 0 to 5.0 wt. %, Cu is present at 0 to 5.0 wt. %, Nb is present at 0 to 1.0 wt. %, Si is present at 0 to 1.0 wt. % and N is present at 0 to 0.25 wt. %. Accordingly, one may again select four elements, five elements or all size elements from C, Mn, Cu, Nb, Si and N. More preferably, the level of Mn may be in the range of up to 4.0 wt. %, or up to 3.0 wt. %, or in the range of up to 2.0 wt. %. Even more preferably, the level of Mn may be in the range of 0.1 wt. % to 2.0 wt. %.

In addition, it has also been found that alloy 9 in the above referenced Table 1 has particular utility herein. Accordingly, it is further contemplated that one may utilize herein a metal alloy in particle form, comprising, consisting essentially of, or consisting of Fe at 82.0 wt. % to 86.0 wt. %; Cr at 10.5 to 12.0 wt. %; Ni at 1.5 to 2.5 wt. %; Mo at 0.8 wt. %. to 1.1 wt. %, C at 0.14 to 0.19 wt. %, Nb at 0.02 to 0.06 wt. %, N at 0.04 to 0.09 wt. % and Si at 0.25 wt. %-0.75 wt. %. As can be seen, such alloy preferably does not contain any Cu or Mn.

The metal alloy is supplied to the PBF process in powder particle or wire form and is preferably produced using conventional melting with either gas, centrifugal, atomization utilizing gases such as nitrogen or argon gas, or water atomization. Nitrogen gas melting and atomization can be used to increase the nitrogen content in the powder alloy. The powder particles can have a diameter in the range of 1 to 200 microns, more preferably from 3 to 70 microns, and most preferably from 15 to 53 microns.

PBF parts are preferably built from the metal alloy herein using commercially available conventional PBF machines such as the SLM®280HL or EOS M-280 and a Trumpf TRUMAFORM LF 250. The parts are preferably built in a nitrogen or argon atmosphere. Parts may be built on a metal substrate that is preheated up to 300° C., such as in the range of 100° C. to 300° C., and more preferably in the range of 20° C. to 200° C. In addition, no preheating of the substrate can be employed. For the PBF procedure herein one may utilize one or a plurality of lasers or electron beams with an energy density of 30 to 500 J/m³, more preferably in the range of 50 J/mm³ to 300 J/m³ and most preferably in the range of 60 J/mm³ to 200 J/mm³.

The metal substrate is preferably composed of the alloys 1-12 in Table 1 or from other materials e.g. from type 304L stainless steel. The PBF procedure herein contemplates a build-up of individual layers each having a thickness typically in the range of 2.0 microns to 200.0 microns, more preferably 5.0 microns to 150.0 microns, and most preferably 5.0 microns to 120.0 microns. Accordingly, a suitable range of thickness for the built-up layers is 2.0 microns and higher. More commonly, however, the thickness range for the built-up layers (combination of individual layers) is from 2 microns to 800 mm and even higher depending upon the capability or requirements of a given printing procedure.

Porosity and cracking in parts can negatively affect a number of part properties including strength, toughness, and fatigue resistance. As such, it is desired for dense parts to minimize porosity and cracking in PBF parts. Porosity in parts is preferably less than 1.0%, more preferably less than 0.5%, and most preferably less than 0.2% although some large parts can tolerate higher porosity levels, such as a porosity of greater than 1.0% to 15.0%. Low porosity and no cracking in the as-built PBF parts with the metal alloys herein is evidenced in the cross-sectional optical micrograph images shown in FIGS. 1-3 which were taken from parts built with alloy 1 (A10) on SLM 280HL and Trumpf TRUMAFORM LF 250 PBF machines, and an EOS M280/290, respectively. The parts shown in FIGS. 1-3 were built on a substrate with no preheating to a height of 10 mm, using 0.040 mm thick layers, for a total of 250 layers in the parts. Porosity is measured with optical image analysis at 100× magnification and alloy 1 show porosity of less than 0.2%.

PBF parts are preferably heat treated after the parts are built to be able to achieve relatively high hardness, strength, and ductility. Achieving high hardness in-situ with building parts without cracking is relatively difficult due to the thermal stresses and thermal fatigue in the parts as they are built, combined with the typically low toughness and ductility of high hardness alloys. PBF uses an energy source to create a small, quickly traversing, molten metal weld pool to selectively melt the powder in a powder layer, which then re-solidifies adding the next layer in the part. The heat of the traversing weld pool is largely conducted into the part, which results in raising the overall part temperature and providing relatively large temperature gradients in the local vicinity of the weld pool. Large continuous and cyclic thermal stresses can arise in parts during PBF part building due to the thermal gradients and phase transformations in the parts. Parts therefore preferably have sufficient strength, toughness, and ductility to resist crack formation under the localized stress conditions and resist crack propagation under the continuous and cyclic stresses.

“As-Built” alloy properties: Table 2 shows comparative mechanical properties of PBF parts produced with commercial PBF steel alloys and alloy 1 (A10) from Table 1 in the as-built condition (without a post-heat treatment). Properties of alloy 1 (A10) were measured on parts that were PBF built on a substrate with no preheating to a height of 10 mm, using 0.040 mm thick layers, for a total of 250 layers in the parts. Table 2 shows the increased hardness and strength of the metal alloy herein over the commercially applied crack-free steel alloys.

TABLE 2 Tensile Yield Strength Strength Elongation Hardness Alloy [MPa] [MPa] [%] [HV] 316L 640 530 40 171 17-4PH 930 586 25 230 M300 1100 1050 10 332 Alloy 1 1504 1254 17 454 (A10)

With respect to the hardness data in Table 2, it is worth noting that the reported hardness is such that it is observed to be a function of the alloy composition as well as the printing procedure employed. Accordingly, in the case of, e.g. M300, the printing hardness may vary, depending upon the printing procedure, such that the HV hardness may be in the range of 320 to 370.

Table 3 below now provides the mechanical properties for all the alloys identified in Table 1 in the “AB” or as-built condition, without a heat treatment and in condition “B1” which is reference to a heat treatment, which heat treatment is discussed further herein:

TABLE 3 Test Hard. YS UTS Elong. Alloy Condition (HV) (MPa) (MPa) (%) 1 (A10) AB 454 1254 1504 17 B1 502 1325 1659 16 4 AB 450 1048 1082 3 B1 491 995 1011 1 5 AB 531 1207 1659 19 B1 556 1338 1785 10 6 AB 381 649 1422 19 B1 519 1329 1631 12 7 AB 415 1003 1538 20 B1 574 1571 1880 6 8 AB 455 1041 1274 8 B1 561 1345 1629 13 9 AB 474 1274 1552 15 B1 531 1337 1676 14 10 AB 438 979 1191 7 B1 564 1368 1637 10 11 AB 501 1090 1365 7 B1 563 1438 1621 5

As may therefore be appreciated from the above, the alloys herein, in the as-built condition (no heat treatment) are such that they indicate a tensile strength of at least 1000 MPa, more preferably at least 1100 MPa, or at least 1200 MPa, and even more preferably, at least 1300 MPa. Moreover, it can now be appreciated that the tensile strength of the as built alloys herein falls in the range of 1000 MPa to 1900 MPa, or 1100 MPa to 1900 MPa, or 1200 MPa to 1900 MPa or 1300 MPa to 1900 MPa.

The above tensile strength is achieved in combination with a yield strength of at least 640 MPa, or at least 700 MPa, or at least 800 MPa, or at least 900 MPa, or at least 1000 MPa, or at least 1100 MPa, or at least 1200 MPa, or at least 1300 MPa, or at least 1400 MPa or at least 1500 MPa. Moreover, it can now be appreciated that the yield strength of the as built alloys herein falls in the range of 640 MPa to 1500 MPa.

Moreover, the above tensile strength and yield strength is also preferably achieved in combination with an elongation of at least 3%, 4%, 5%, 6%, 7%, 8%, 9%, 10%, 11%, etc. up to 25%. Moreover, it can be appreciated that the elongation of the as built alloys herein falls in the range of 3% to 25%.

The above tensile strength, yield strength and elongation is then preferably achieved in combination with a hardness (HV) value of at least 375, 400, 410, 420, 430, 440, etc. up to 600. Moreover, it can be appreciated that the HV values of the alloys herein fall in the range of 375 to 600. It is worth noting that alloy 12 herein indicated an HV value of 420-600.

Accordingly, it should be appreciated that the alloys herein are such that they can provide in the as built condition a tensile strength of at least 1000 MPa, a yield strength of at least 640 MPa, and elongation of at least 3% and a hardness (HV) value of at least 375. Other combinations of tensile strength, yield strength, elongation and hardness may now be selected from the individual preferred levels of tensile strength, yield strength, elongation and hardness noted herein for the non-heat treated alloy.

FIG. 4 shows a 10,000×, secondary electron, scanning electron microscopy (SEM) micrograph of a PBF-produced, as-built, alloy 1 (A10) part. The part shown in FIG. 4 was built on a substrate with no preheating to a height of 10 mm, using 0.040 mm thick layers, for a total of 250 layers in the parts. SEM imaging was performed on a Jeol JSM-7001F Field Emission SEM. The microstructure in FIG. 4 is contemplated to contain the BCC/martensite, FCC, M₂CN, and M₇C₃.

FIG. 5 shows the alloy 1 (A10) equilibrium phase diagram produced with Thermo-Calc showing the phase fraction of each phase that is thermodynamically stable over a temperature range from 20° C. to 1500° C. The equilibrium phase diagram was used to identify the phases with the highest potential to contribute to increasing hardness and strength.

It is contemplated that the elevated temperature of PBF parts during building, which is caused by heat transfer to the part from the traversing weld pool, may be sufficiently high in the metal alloys herein to drive in-situ precipitation of secondary phases such as the Cu-rich FCC phase, the M₂N ((Cr,Mo)₂N) phase, and the M₂₃C₆ ((Cr,Fe,Mo)₂₃C₆) phase shown in the FIG. 5 phase diagram for alloy 1 (A10). The in-situ precipitation of these phases during the part build is expected to contribute to the part strength and hardness in the as-built condition.

“Heat Treatment”: PBF parts produced with the metal alloys herein can be further enhanced by heat treating to increase the strength and hardness of the parts. It is contemplated that various heat treatments can be performed to affect the part properties and the heat treatment temperatures can be selected from equilibrium phase diagrams.

Effective heat treatments for the metal alloys herein are contemplated to include (1) high temperature solutionizing (dissolving one or more of the secondary phases), quenching, and tempering (precipitation of the secondary phases) and/or (2) tempering of the as-built part, with each heat treating step being performed in a vacuum, argon, or nitrogen atmosphere. Solutionizing is preferably performed at a temperature of greater than 900° C., and for example in the range of 900° C. to 1400° C. and tempering is preferably performed at a temperature in the range of 150-900° C.

The high temperature solutionizing and quenching step is contemplated to:

-   -   a. reduce anisotropy in the part that can result from the PBF         process,     -   b. increase martensite content and thereby hardness and possibly         strength     -   c. dissolve Cr carbides and/or Cr nitrides that can negatively         affect the corrosion resistance of the part,     -   d. coarsen the undissolved carbides and/or nitrides.     -   (2) Further strengthening and hardening of the part via         additional precipitation of various phases is contemplated to be         initiated by subsequent tempering treatments.

“Heat Treatment”—procedure: The equilibrium phase diagram in FIG. 5 was used to select solutionizing and tempering temperatures for PBF parts from alloy 1 (A10). The heat treatment used on the alloy 1 (A10) PBF parts consisted of solutionizing at 1000° C. for 1.5 hr followed by a gas quench to −84° C. for 2 hours, and finally tempering at 454° C. for 48 hr in Argon to strengthen and harden the part.

“Heat Treated”—alloy properties: Properties of the heat treated PBF alloy 1 (A10) parts are shown in Table 4 along with commercial PBF steel alloys after subjecting them to their manufacturer-prescribed heat treatments for PBF parts. Properties of heat treated alloys 1, 4, 5, 6, 7, 9, 0, 10 and 11 were also listed in Table 3. Properties of alloy 1 (A10) were measured on heat treated parts that were PBF built on a substrate with no preheating to a height of 10 mm, using 0.040 mm thick layers, for a total of 250 layers in the parts. The hardness of alloy 1 (A10) shown in Table 4 was taken at the surface of the heat treated part.

TABLE 4 Tensile Yield Strength Strength Elongation Hardness Alloy [MPa] [MPa] [%] [HV] 316L 843 587 28 262 17-4PH 1100 590 29 311 M300 2050 1990 2 544 Alloy 1 1659 1325 16 502 (A10)

As may therefore be appreciated from Tables 3 and 4, the alloys herein following heat treatment are such that they indicate a tensile strength of at least 1000 MPa, or at least 1100 MPa, or at least 1200 MPa, or at least 1300 MPa, or at least 1400 MPa, or at least 1500 MPa, or at least 1600 MPa, or at least 1700 MPa, or at least 1800 MPa. Moreover, it can be appreciated that the heat-treated alloys have a tensile strength in the range of 1000 MPa to 1900 MPa.

Such tensile strength is achieved in combination with a yield strength of at least 900 MPa, or at least or at least 1000 MPa, or at least 1100 MPa, or at least 1200 MPa, or at least 1300 MPa, or at least 1400 MPa, or at least 1500 MPa, or at least 1600 MPa. Moreover, it can be appreciated that the heat-treated alloys herein have a yield strength in the range of 900 MPa to 1600 MPa.

Such tensile strength and yield strength is also preferably achieved in combination with an elongation of at least 1%, 2%, 3%, 4%, 5%, 6%, 7%, 8%, 9%, 10%, etc. up to 16%. Moreover, it can be appreciated that the heat-treated alloys herein have elongation values in the range of 1% to 16%.

Such tensile strength, yield strength and elongation is then preferably achieved in combination with a hardness (HV) value of at least at least 475, or at least 500, or at least 525, or at least 550, or at least 600. Moreover, it can be appreciated that the heat-treated alloys herein have HV values in the range of 475 to 650.

Accordingly, it should be appreciated that the alloys herein with heat treatment are such that they can provide, e.g., a tensile strength of at least 1000 MPa, a yield strength of at least 900 MPa, and elongation of at least 1% and a hardness (HV) value of at least 475. Other combinations of tensile strength, yield strength, elongation and hardness may now be selected from the individual preferred levels of tensile strength, yield strength, elongation and hardness noted herein for the heat treated alloy.

Table 4 shows that heat treatment does not raise the hardness of 316L and 17-4PH to a level that either alloy could be classified as a hard alloy (HV>370). Only the hardness value of M-300 after heat treatment classifies the alloy as a hard alloy (HV>370) and M300 is currently the primary alloy choice in additive manufacturing when a hard alloy is required. However, the application space of M-300 is highly limited since M300 features at such hardness levels indicate only a low elongation (2%), indicating a tendency for parts to fracture or undergo chipping when exposed to even small impact force such as dropping the part to the floor. Therefore, the application of M300 finds relatively limited industrial use. Additionally, the M300 alloy contains a significant concentration of relatively high-cost elements (18 wt. % Ni, 9 wt. % Co, and 5 wt. % Mo) and as such would not be considered a low-cost alloy further limiting its industrial use. Finally, the industrial use of M-300 is further limited due to its potential EH&S and product stewardship risks given its high cobalt content. Cobalt is known to be a health risk upon inhalation and a stewardship risk due to its classification as a conflict mineral since it is mainly sourced from the Republic of Congo.

In contrast, the heat-treated alloy 1 (A10) has numerous benefits compared to the current incumbent M300. Alloy 1 (A10) has a higher hardness, a higher elongation, a lower cost structure, and is preferably cobalt free.

Case Hardening Treatment—The surface hardness of PBF parts produced with the metal alloys herein can be further enhanced by carburizing and nitriding case hardening treatments. These treatments introduce carbon and nitrogen, respectively, to the surface of the part, creating a case layer with increased hardness relative to the “as-built” or “heat-treated” conditions while retaining the heat treated properties in the core. It is contemplated that other treatments employed for case hardening such as carbonitriding can also be used.

Carburizing—The carburizing process for the metal alloys herein preferably includes a combination of the following steps: oxide reduction, carburizing, solutionizing, quenching, and tempering. Oxide reduction is performed in a reducing atmosphere at temperatures preferably between 800° C. and 1200° C., more preferably between 900° C. and 1150° C., and most preferably between 950° C. and 1100° C. Carburizing is performed by a method that provides or generates a source of carbon in the atmosphere or environment surrounding the part, such as pack, gas, vacuum, liquid, and plasma carburizing, at temperatures preferably between 800° C. and 1000° C., more preferably between 850° C. and 975° C., and most preferably between 875° C. and 950° C.

The carburization results in an enrichment of carbon at the surface of the part resulting in a layer of material with a different microstructure compared to that of the core as seen at two different magnifications in FIG. 6 for alloy 5. This structure results in a maximum hardness at the exterior surface that is preferably 650 to 1000 HV, more preferably 700 to 975 HV, and most preferably 800 to 950 HV. The hardness then progressively decreases with increasing distance from the exterior surface (i.e. depth into the part) until it reaches a steady-state value in the core similar to heat treated values discussed herein. Representative examples of the hardness as a function of depth in carburized case hardened alloys 5 and 8 are seen in FIG. 7 . Other alloys listed herein can similarly be case hardening by a carburizing process with similar effectiveness. The level of carbon can be increased at the surface down to a depth of at least 2.0 mm, and up to 4.0 mm.

Nitriding—The nitriding process for the metal alloys herein includes a combination of the following steps: solutionizing, quenching, and tempering. It is contemplated that the nitrogen may be introduced to the surface of the part by other nitriding methods, including plasma and liquid nitriding processes. The enrichment of nitrogen at the surface of the part results in a layer of material with a different microstructure compared to that of the core as seen at two different magnifications for alloy 9 (Table 1) are illustrated in FIG. 8 . This structure results in a maximum hardness at the exterior surface that is preferably 700 to 1300 HV, more preferably 750 to 1250 HV, and most preferably 825 to 1225 HV. The hardness then progressively decreases with increasing distance from the exterior surface (i.e. depth into the part) until it reaches a steady-state value in the core similar to heat treated values discussed herein. Representative examples of the hardness as a function of depth in nitrided case hardened alloys 8 and 9 are seen in FIG. 9 . As can be seen, the level of nitrogen is increased from the surface down to a depth of at least 200 μm and up to 400 μm. Other alloys listed herein can similarly be case hardened by a nitriding process with similar effectiveness. 

What is claimed is:
 1. An alloy for 3D printing of a metallic part, the alloy comprising: C is present at 0.1 to 0.35 wt. %, based on the total weight of the alloy, Cr is present at 10.0 wt. % to 19.0 wt. %, based on the total weight of the alloy, Mo is present at 0.5 wt. % to 3.0 wt. %, based on the total weight of the alloy; and at least two elements from the group consisting of Ni, Cu, Nb, Si and, wherein if present Ni is present at 0 to 5.0 wt. %, based on the total weight of the alloy, wherein if present Cu is present at 0 to 5.0 wt. %, based on the total weight of the alloy, wherein if present Nb is present at 0 to 1.0 wt. %, based on the total weight of the alloy, wherein if present Si is present at 0 to 1.0 wt. %, based on the total weight of the alloy, and wherein if present N is present at 0 to 0.25 wt. %, based on the total weight of the alloy; and the balance of the alloy composition containing Fe.
 2. The alloy of claim 1, wherein Cr is present at 10.0 wt. % to 18.3 wt. %, C is present at 0.1 to 0.30 wt. %, Mo is present at 0.5 wt. % to 2.5 wt. %, Ni is present at 0 to 4.0 wt. %, Cu is present at 0 to 4.0 wt. %, Nb is present at 0 to 0.7 wt. %, Si is present at 0 to 0.7 wt. % and N is present at 0 to 0.25 wt. %.
 3. The method of claim 1, wherein Cr is present at 10.5 wt. % to 19.0 wt. %.
 4. The alloy of claim 1, wherein Mo is present at 0.89 wt. % to 3.0 wt. %.
 5. The alloy of claim 1, wherein C is present at 0.1 wt. % to 0.25 wt. %.
 6. The alloy of claim 1, wherein the alloy includes at least three elements selected from the group consisting of Ni, Cu, Nb, Si and N.
 7. The alloy of claim 1, wherein the alloy includes at least four elements selected from the group consisting of Ni, Cu, Nb, Si and N.
 8. The alloy of claim 1, wherein the alloy includes Ni, Cu, Nb, Si and N.
 9. The alloy of claim 1, wherein the alloy, when printed, is capable of forming a metallic part having the following properties: tensile strength of at least 1000 MPa, yield strength of at least 640 MPa, elongation of at least 1.0%, hardness (HV) of at least
 375. 10. The alloy of claim 1, wherein the alloy, when printed, is capable of forming a metallic part having the following properties: a tensile strength of 1000 MPa to 1900 MPa, a yield strength of 640 MPa to 1500 MPa, an elongation of 1.0% to 25.0%, and a hardness (HV) of 375 to
 600. 11. The alloy of claim 1, wherein the alloy, when printed, is capable of forming a metallic part having the following properties: a tensile strength of at least 1000 MPa, a yield strength of at least 900 MPa, an elongation of at least 1.0% and a hardness (HV) of at least
 475. 12. The alloy of claim 1, wherein the alloy is in a powder form.
 13. The alloy of claim 12, wherein the powder form has >10% wt. particles with a diameter in the range of 1 to 200 microns.
 14. The alloy of claim 12, wherein the powder form has >5% wt. particles with a diameter in the range of 3 to 70 microns.
 15. The alloy of claim 12, wherein the powder form has >5% wt. particles with a diameter in the range of 15 to 53 microns.
 16. A method of producing a metal alloy, the method comprising: supplying an alloy comprising: C at 0.1 to 0.35 wt. %, based on the total weight of the alloy, Cr at 10.0 wt. % to 19.0 wt. %, based on the total weight of the alloy, Mo at 0.5 wt. % to 3.0 wt. %, based on the total weight of the alloy; and at least two elements from the group consisting of Ni, Cu, Nb, Si and, wherein if present Ni is present at 0 to 5.0 wt. %, based on the total weight of the alloy, wherein if present Cu is present at 0 to 5.0 wt. %, based on the total weight of the alloy, wherein if present Nb is present at 0 to 1.0 wt. %, based on the total weight of the alloy, wherein if present Si is present at 0 to 1.0 wt. %, based on the total weight of the alloy, and wherein if present N is present at 0 to 0.25 wt. %, based on the total weight of the alloy; and the balance of the alloy composition containing Fe; melting the alloy; atomizing the melted alloy to form a powder metal alloy.
 17. The method of claim 16, wherein the atomization comprises at least one of gas atomization, water atomization or centrifugal atomization.
 18. The method of claim 16, further comprising 3D printing the powder metal alloy to form a metallic part by at least in part by a solid-liquid-solid phase transformation.
 19. The method of claim 18, wherein the solid-liquid-solid phase transformation comprises at least in part powder bed fusion (PBF).
 20. The method of claim 16, wherein the powder metal alloy has >10% wt. particles with a diameter in the range of 1 to 200 microns. 